Impact of pollution caused by salmon breeding centers on river water quality

Document Type : Research Paper

Authors

1 Anesthesia Techniques Department, Al-Mustaqbal University College, Babylon, Iraq

2 Advanced Biomedical Science, Al-Nisour University College, Baghdad, Iraq

3 Medical Technical College, Al-Farahidi University, Baghdad, Iraq

4 College of pharmacy, Ahl Al Bayt University, Kerbala, Iraq

5 Department of Anesthesia, College of Health and Medical Technology, Al-Ayen University, Thi-Qar, Iraq

6 Belgorod State National Research University, 85, Pobedy St, Belgorod, 308015, Russian Federation

10.22124/cjes.2022.6067

Abstract

The expansion of aquaculture and the need for its development in tandem with environmental criteria demonstrate this importance. Among these effects is the introduction of untreated sewage from salmon breeding centers into river water, which can negatively impact aquatic ecosystems. The present study was conducted to assess the impact of salmon breeding facilities on the Iraqi Euphrates River's water quality. The physical and chemical parameters of river water were measured at ten stations during the environmental surveys to determine the scope and limits of pollution changes. Six samples were collected from each station over one year, from January 2020 to January 2021. SPSS 23 software was used to conduct statistical analyses using analysis of variance (ANOVA) and Duncan's post hoc test. According to the ANOVA test's significant values, there was no statistically significant difference in the amount of TDS (p < 0.05). The remaining parameters sampled in different months exhibited significant differences (p > 0.05). Nitrate (F = 67.12), Phosphate (F = 96.53), DO (F = 22.08), BOD (F = 6.81), COD (F = 17.48) and TSS (F = 32.92) were determined to be the parameter values. The study's findings generally confirm the significant impact of fish breeding ponds on the quality of surface water resources. As a result, special attention should be prevent environmental complications through correct and principled aquaculture.

Keywords

References

Belliard, J, Beslagic, S, & Tales, E 2020, Changes in fish communities of the Seine Basin over a long-term perspective. The Seine River basin. Handbook of environmental chemistry. Springer, Cham. https://doi. org/10.1007/698_2019_380.
Burke, M, Grant, J, Filgueira, R, & Stone, T 2021, Oceanographic processes control dissolved oxygen variability at a commercial Atlantic salmon farm: application of a real-time sensor network. Aquaculture, 533, 736143.
Chow, MI, Lundin, JI, Mitchell, CJ, Davis, JW, Young, G, Scholz, NL, & McIntyre, JK 2019, An urban stormwater runoff mortality syndrome in juvenile coho salmon. Aquatic Toxicology, 214, 105231.
Compton, JE, Andersen, CP, Phillips, DL, Brooks, J R, Johnson, MG, Church, MR, McComb, BC 2006, Ecological and water quality consequences of nutrient addition for salmon restoration in the Pacific Northwest. Frontiers in Ecology and the Environment, 41: 18-26.
Davidson, J, Redman, N, Crouse, C, & Vinci, B 2022, Water quality, waste production, and off‐flavor characterization in a depuration system stocked with market‐size Atlantic salmon Salmo salar. Journal of the World Aquaculture Society, https://doi.org/10.1111/jwas.12920.
Encina-Montoya, F, Boyero, L, Tonin, AM, Aguayo, MF, Esse, C, Vega, R & Nimptsch, J 2020, Relationship between salt use in fish farms and drift of macroinvertebrates in a freshwater stream. Aquaculture Environment Interactions, 12: 205-213.
Farabi, S M V, Golaghaei, M, Sharifian, M & Karimian, E 2022, Effects of rainbow trout farming on water quality around the sea farms in the south of the Caspian Sea. Caspian Journal of Environmental Sciences, 20: 729-737.
Gholami, V, Mohseni Saravi, M & Ahmadi, H 2010, Effects of impervious surfaces and urban development on runoff generation and flood hazard in the Hajighoshan watershed. Caspian Journal of Environmental Sciences, 8: 1-12.
Hamilton, S, Murphy, C, Johnson, S & Pollock, A 2022, Water quality ramifications of temporary drawdown of Oregon reservoirs to facilitate juvenile Chinook salmon passage. Lake and Reservoir Management, 38: 165-179.
Hause, CL, Singer, GP, Buchanan, RA, Cocherell, DE, Fangue, NA, & Rypel, AL 2022, Survival of a threatened salmon is linked to spatial variability in river conditions. Canadian Journal of Fisheries and Aquatic Sciences.
Holmes, EJ, Saffarinia, P, Rypel, AL, Bell-Tilcock, MN, Katz, JV, & Jeffres, CA 2021, Reconciling fish and farms: Methods for managing California rice fields as salmon habitat. PlosOne, 16: e0237686
Hukom, V, Nielsen, R, Asmild, M, & Nielsen, M 2020, Do aquaculture farmers have an incentive to maintain good water quality? The case of small-scale shrimp farming in Indonesia. Ecological Economics, 176: 106717
Kochalski, S, Riepe, C, Fujitani, M, Aas, Ø & Arlinghaus, R 2019, Public perception of river fish biodiversity in four European countries Conservation Biology, 33: 164-175
Koed, A, Birnie‐Gauvin, K, Sivebæk, F, & Aarestrup, K 2020, From endangered to sustainable: Multi‐faceted management in rivers and coasts improves Atlantic salmon Salmo salar populations in Denmark. Fisheries Management and Ecology, 27: 64-76
Koralay, N, & Ömer, K 2018, Forestry activities and surface water quality in a rainfall watershed. European Journal of Forest Engineering, 4: 70-82
Kristensen, T, Åtland, Å, Rosten, T, Urke, H, & Rosseland, B 2009, Important influent-water quality parameters at freshwater production sites in two salmon producing countries. Aquacultural Engineering, 41: 53-59
Kroglund, F, Rosseland, B, Teien, H-C, Salbu, B, Kristensen, T, & Finstad, B 2008 Water quality limits for Atlantic salmon Salmo salar L exposed to short term reductions in pH and increased aluminum simulating episodes. Hydrology and Earth System Sciences, 122: 491-507
Maest, A, Prucha, R, & Wobus, C 2020 Hydrologic and water quality modeling of the pebble mine project pit lake and downstream environment after mine closure. Minerals, 10: 727
Malik, D, Sharma, AK, Sharma, AK, Thakur, R, & Sharma, M 2020, A review on impact of water pollution on freshwater fish species and their aquatic environment. Advances in Environmental Pollution Management: Wastewater Impacts and Treatment Technologies, 1: 10-28
Meshesha, T W, Wang, J, & Melaku, N D 2020, Modelling spatiotemporal patterns of water quality and its impacts on aquatic ecosystem in the cold climate region of Alberta, Canada. Journal of Hydrology, 587: 124952
Quiñones, RA, Fuentes, M, Montes, RM, Soto, D, & León‐Muñoz, J 2019, Environmental issues in Chilean salmon farming: a review Reviews in Aquaculture, 11: 375-402
Rahbar, M, Nezami, S, Khara, H, Rezvani, M, & Eslami, S 2011, Effect of age on reproductive performance in female Caspian brown trout Salmo trutta caspious, Kessler 1877. Caspian Journal of Environmental Sciences, 9: 97-103
Saltveit, SJ, Brabrand, Å, & Brittain, JE 2019 Rivers need floods: Management lessons learnt from the regulation of the Norwegian salmon river, Suldalslågen. River Research and Applications, 35: 1181-1191
Thorstad, EB, Bliss, D, Breau, C, Damon‐Randall, K, Sundt‐Hansen, LE, Hatfield, EM & Sheehan, T 2021, Atlantic salmon in a rapidly changing environment-Facing the challenges of reduced marine survival and climate change. Aquatic Conservation: Marine and Freshwater Ecosystems, 31: 2654-2665
Varol, M 2019 Impacts of cage fish farms in a large reservoir on water and sediment chemistry Environmental Pollution, 252: 1448-1454
Yilmaz, E, & Koç, C 2014 Physically and chemically evaluation for the water quality criteria in a farm on Akcay. Journal of Water Resource and Protection, 6 (2), DOI: 10.4236/jwarp.2014.62010.
Caspian Journal of Environmental Sciences
Volume 20, Issue 5
Special Issue: Economical Aspects of Environmental Studies
December 2022
Pages 1039-1045

Files

Share

How to cite

Statistics